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Abstract

Background

Hepatic encephalopathy (HE) is a reversible neuropsychiatric syndrome associated with
acute and chronic liver diseases. It includes a number of neuropsychiatric disturbances
including impaired motor activity and coordination, intellectual and cognitive function.

Results

In the present study, we used a chronic rat HE model by ligation of the bile duct
(BDL) for 4 weeks. These rats showed increased plasma ammonia level, bile duct hyperplasia
and impaired spatial learning memory and motor coordination when tested with Rota-rod
and Morris water maze tests, respectively. By immunohistochemistry, the cerebral cortex
showed swelling of astrocytes and microglia activation. To gain a better understanding
of the effect of HE on the brain, the dendritic arbors of layer V cortical pyramidal
neurons and hippocampal CA1 pyramidal neurons were revealed by an intracellular dye
injection combined with a 3-dimensional reconstruction. Although the dendritic arbors
remained unaltered, the dendritic spine density on these neurons was significantly
reduced. It was suggested that the reduction of dendritic spines may be the underlying
cause for increased motor evoked potential threshold and prolonged central motor conduction
time in clinical finding in cirrhosis.

Conclusions

We found that HE perturbs CNS functions by altering the dendritic morphology of cortical
and hippocampal pyramidal neurons, which may be the underlying cause for the motor
and intellectual impairments associated with HE patients.

Keywords:

Background

Hepatic encephalopathy is a common disease caused by the liver failure. The consequential
disorders of the liver include the cirrhosis, hepatitis, urea cycle defect or lack
of blood circulation to the liver [1]. The exact cause of hepatic encephalopathy is still unclear, but ammonia [the term
“ammonia” refers to total ammonia:gas (NH3) + ion (NH4+)] may be involved [2]. Ammonia is a metabolite which is mostly produced within the gut during protein digestion
and deamination. It can diffuse into the capillaries of gut, and thence transferred
to the hepatocytes for urea cycle [3]. The liver maintains the concentration of ammonia in the systemic circulation [4]. Hyperammonaemia develops if the urea cycle cannot control the ammonia overload.
Ammonia crosses the blood-brain barrier readily, and it enters the brain from blood
by diffusion rather than via a saturable transport system. The brain uptake index
for ammonia is independent of arterial ammonia levels over a wide range of concentrations.
It is known that the brain has a highly integrated system whose astrocytes are endowed
with glutamine synthetase that protect it against serum derived toxicity. The ammonia
is detoxified temporarily by its incorporation into the non-toxic amino acid glutamine,
but continual hyperammonemic assault would induce glutamine accumulation in the cytoplasm
and mitochondria. The glutamine in mitochondria is subsequently hydrolyzed leading
to high levels of ammonia. This triggers oxidative and nitrosative stress, the mitochondrial
permeability transition and mitochondrial injury, a sequence of events that have been
termed as the Trojan horse hypothesis of HE [5,6].

HE has a lot of symptoms, and most of them are closely related to the functions of
the central nervous system. These comprise brain edema, intracranial hypertension
and a number of neuropsychiatric disturbances such as somnolence, confusion, sleep-wake
inversions, impairments of sensory-motor integration, cognitive performance, attention
and memory, or even coma [2,7]. High ammonia level is believed to be the cause for neuropsychiatric disturbances
[2]. Brain imaging confirms that hyperammonemic neonates and infants show cortical atrophy,
ventricular enlargement, demyelination or gray and white matter hypodensities [8-10]. Some structural alterations have been associated with the deleterious effects of
hyperammonemia. Astrocytes which are metabolically hyperactive, appeared to undergo
histological changes in hyperammonemic brain [11,12]. Some studies have reported that the inhibitory and excitatory neurotransmission
might be directly affected by ammonia toxicity. The excitotoxicity induced by hyperammonemia
would further trigger the production of nitric oxide synthases (NOS), increase in
oxidative stress such as increased production of reactive oxygen and nitrogen oxide
species (ROS/RNOS). Thus, in HE model, there is evidence of over-expression of nNOS
in the cerebral cortex [13], cerebellum [14,15] and striatum [16]. However, the effects of ammonia on central neurons have remained elusive. In view
of this, we have used an intracellular dye injection technique along with behavioral
tests to investigate whether the behavioral defects in bile duct ligation-induced
HE model might be correlated with the changes of dendritic structures of cortical
pyramidal neurons.

Methods

Animals

Thirty male Sprague-Dawley (SD) rats weighing 250-350 g were used for the study. The
rats were divided into three groups. Of these, 20 of them were subjected to the common
bile duct ligation to induce liver fibrosis and they were allowed to survive for 4
weeks. The surgery of common bile duct ligation followed previous protocol [17]. Briefly, the rats were operated under deep anaesthesia with ketamine and xylazine
(8 mg ketamine and 1 mg xylazine/100 g body weight) and a double surgical ligation
was placed (2 silk knots proximal to bifurcation were tied on common duct) and the
common bile duct was sectioned between both knots. The surgical rats were divided
into two groups. Firstly, half of the rats were fed with normal diet for 4 weeks (BDL,
n = 10). As in previous article [18], feeding ammonium acetate could increase blood ammonia level, so some BDL rats in
our study were fed with diet containing ammonium acetate (BDLHD, 10% w/w) for last
2 weeks (n = 10) to exacerbate the liver dysfunction. Ten rats served as sham-operated
controls. Rats were caged individually with water ad libitum in a temperature (24 ± 1°C)
and humidity-controlled room with 12-hour on, 12-hour off lighting schedule. All experimental
procedures were approved by the Animal Care and Use Committee of the National Chung-Hsing
University under guidelines of the National Science Council of Taiwan.

Behavioral tests

The protocols were modified from Jones and Roberts [19] and Chen et al. [20] to evaluate the motor coordination and spatial learning memory performance of the
rats. All rats were subjected to rotarod and Morris water maze tasks before been scheduled
for surgical operation and sacrifice.

Rotarod test

The motor coordination of HE rats was assessed with an accelerating rotarod apparatus
(Ugo Basile, Comerio, Italy) [19]. Rats were trained twice a day for two consecutive days prior to testing. Training
sessions consisted of maintaining the rats on the rod for 3 min at the speed (12 rpm).
In the test, the rats were evaluated for 3 min in the session, in which the rotation
rate increases constantly to reach 12 rpm and the direction of rotation was reversed
with each 12 seconds. The mean latency to fall off the rotarod was recorded as the
mean of three trials for each rat.

Morris water maze task

Animal performance was recorded with a video camera for subsequent analysis of the
path and swimming speed. The maze apparatus consisted of a circular pool 200 cm in
diameter and 60 cm deep. The pool was filled with water at approximately 23°C to a
height of 50 cm. A transparent platform (diameter 15 cm) was placed at a constant
position 2-3 cm below the surface of the water. The visual cues arrayed around the
room were made available for the rats to learn the location of the hidden platform.
The rats were tested for 3 consecutive days with two trials per day. Rats were allowed
to remain on the platform for 20 s if escaped within 180 s, or alternatively placed
on the platform and remained there for 20 s if failed to locate the underwater platform
within 180 s. A recovery period of 10 minutes was allowed between the two trials.
The escape times of the two trials conducted each day were recorded and averaged.

Tissue preparation

At the end of the survival period the rats in each group were divided into two subgroups.
One (N = 5) is decapitated and processed for ammonia level measuring of cerebral cortex
as described below. The other (N = 5) is sacrified and processed for intracellular
dye injection and immunohistochemical staining as described previously [21]. Briefly, the rats were deeply anaesthetized and perfused with 2% paraformaldehyde
in 0.1 M phosphate buffer (PB), pH 7.3, at room temperature for 30 min. Immediately
following the perfusion, the whole brain was carefully removed and sectioned with
a vibratome (Technical Products International, St. Louis, MO) into 350-μm-thick coronal
slices. Half of the thick slices collected were processed by an intracellular dye
injection to reveal the dendritic arbor of selective individual neurons. The remaining
tissue slices were postfixed in 4% paraformaldehyde in 0.1 M PB for 2 days. They were
then cryoprotected and resectioned into 20-μm sections [21] for studying the cytoarchitecture as described below.

Intracellular dye injection and subsequent immunoconversion of the injected dye

The cerebral neurons whose cell nuclei emitting fluorescence with 10-7 M 4′, 6-diamidino-2-phenyl-indole (DAPI; Sigma-Aldrich, St. Louis, MO) under the
filter set were visualized by an intracellular injection of Lucifer yellow (LY, Sigma-Aldrich)
which emitted a yellow fluorescence [21,22]. For this purpose, the brain slice was placed in a chamber on the stage of a fixed-stage
fluorescence microscope (Olympus BX51) and covered with 0.1 M PB. A glass micropipette
filled with 4% LY in water was steadily positioned with a three-axial hydraulic micromanipulator
(Narishige, Tokyo, Japan) for dye injection. The intracellular amplifier (Axoclamp–IIB)
was used to generate injection current. When the dye injection was completed, the
brain slice were rinsed with 0.1 M PB and postfixed in 4% paraformaldehyde. The brain
slices given dye injection were then cryoprotected and sectioned into 60-μm-thick
serial sections for subsequent immunoconversion.

The sections derived from above were first incubated with 1% H2O2 in PB for 30 min and then incubated in PBS containing 2% Bovine Serum Albumin (Sigma-Aldrich)
and 1% Triton X-100. Sections were then treated with biotinylated rabbit anti-LY (1:200;
Molecular Probes, Eugene, OR) in PBS for 18 hours at 4°C and then with standard avidin-biotin
HRP reagent (Vector, Burlingame, CA) for 1 hour at room temperature. They were then
reacted with 0.05% 3-3′-diaminobenzidine tetrahydrochloride (DAB, Sigma) and 0.01%
H2O2 in 0.05 M Tris buffer. Reacted sections were mounted on subbed slides, air-dried,
and coverslipped in Permount for 3-dimensional reconstruction.

Ammonia colorimetric assay

The blood sample and homogenized cortex were collected and centrifuged with spin filter
(ab93349, Abcam) to remove excessive proteins. After centrifugation, the assays were
performed according to the manufacturer’s specifications (K370-100, BioVision) using
a Microplate Reader (Infinite F50, Tecan Co., Mannedorf, Switzerland) to detect the
level of ammonium ion.

Data analysis

The cell density of microglia, nNOS + and pyramidal neurons in primary sensorimotor
cortex was randomly counted twice in each section per 3402, 13902 and 502 μm2, respectively. Ten sections of each rat were analyzed. The soma area of layer V pyramidal
neurons and astrocytes in primary sensorimotor cortex was reconstructed using a Camera
lucida drawing tube at 100× oil-objective lens in two-dimensional plane. Fifty pyramidal
neurons or astrocytes of each rat were randomly chosen from section to analyze their
soma size. The astrocytes with a clear cell border and all-around processes were chosen
to draw their outline of cell body. In astrocyte end-feet analysis, ten astrocytes
of each rat were analyzed. All terminal boutons in the process end within a radius
of 50 μm around an astrocyte were counted. The demarcation between soma and process
was taken as the point where the convex curvature of the soma became concave [21]. To study the changes of dendritic arbor and length of layer III and layer V pyramidal
neurons, the complete dendritic arbors of 5 neurons in each rat were reconstructed
3-dimensionally with Neurolucida (MicroBrightField, Williston, VT). To determine the
density of dendritic spines, 5 representative CA1 and layer V pyramidal neurons each
from each rat from the respective treatment groups were randomly analyzed. Dendrites
of the studied CA1 and layer V pyramidal neurons were divided into proximal and distal
segments of the apical and basal dendrites following the criteria described before
[20,21]. Briefly, for layer V pyramidal neurons, proximal and distal basal dendrites were
defined as the segments 50–100 μm (around the first to second branch), and 150–200 μm (around the last one or two branches) from where they originate from the soma, respectively.
Proximal apical dendrites were the first or second branch of the apical trunk and
distal apical dendrites were the terminal dendrites after the last branch point in
V pyramidal neurons. For hippocampal CA1 pyramidal neurons, basal dendrites were defined
as those in the stratum oriens while apical dendrites were on the other side of the
cell body layer with the proximal segment in the stratum radiatum and distal segment
in the stratum lacunosum-moleculare as the criteria described before [20]. Data was expressed as mean ± SE unless otherwise indicated. Statistical significance
was tested with one-way analysis of variance (ANOVA) followed by the Newman-Keuls
test to find out any difference between treatment groups.

Results

The H&E stained inferior caudate lobe of the liver was used to evaluate the pathological
changes following the bile duct ligation surgery (Figure 1). The hepatocytes forming the hepatic cords were neatly arranged in the control rat.
After bile duct ligation (BDL) the hepatic cords were noticeably decreased and bile
duct expanded and appeared hyperplasia (Figure 1B and C). In BDLHD rats the bile duct proliferation was more drastic (Figure 1C).

Figure 2.Biochemical values in HE rats. The AST (A), ALT (B) and ammonia levels of serum (C) and cerebral cortex (D) or HE rats were measured. *, p < 0.05 between the experimental rats and sham control.

To explore whether hyperammonemia would alter the sensorimotor cortical function and
spatial learning memory, we next assessed the sensory motor integration with rotarod
(Figure 3A). Both BDL and BDLHD rats maintained a short time in their motor performance, 41.5 ± 12.3%
and 11.3 ± 6.1%, but the BDLHD group was poorer in performance than BDL animals.

Figure 3.Behavioral performances in HE rats. The Rotarod (A) and Morris water maze (B, C and D) tests were analyzed in BDL and BDLHD rats. These data was normalized to those obtained
before HE induction. *, p < 0.05 between the marked and control rat; #, p < 0.05 between
the marked and BDL rats.

For hippocampus-related functions, we assessed the spatial memory with the water maze
task. The BDL and BDLHD rats utilized longer duration, an increase by 2.6 and 4.6
folds, respectively, to locate the hidden platform than the control rats (Figure 3B). This was accompanied by a tripling of the swimming path (Figure 3C). The swimming speed in BDL and BDLHD rats was decreased compared with control rats
but the reduction was not statistically significant.

Morphological changes of cerebral cortex in HE rats

The sensorimotor cortex of BDL and BDLHD rats remained six-layered in structure; there
was no evidence of karyopyknosis in layer III and layer V region. By immunohistochemistry,
the staining intensity of astrocytes in BDL and BDLHD rats increased in comparison
with that in the control rats (Figure 4A-C). In the BDL and BDLHD rats, the soma size of astrocytes was increased by about
55% and 65%, respectively, as compared with that of the control rats (Figure 5A). There was no swollen end-feet around the astrocytes in the control rats. After
BDL surgery, more thickened processes (* in Figure 4B-C) and bouton-like terminals (end-feet, arrow in Figure 4B-C) were observed at high magnification. The number of end-feet around each astrocyte
in BDL and BDLHD rats was 5.7 ± 0.82 and 6.2 ± 0.95, respectively. Iba1-immunoreactivated
microglia was counted and analyzed (Figure 4D-F). Based on the external morphology, the Iba1+ glia cells could be divided into
inactivated (insert in Figure 4D) and activated microglia (inserts in Figure 4E and F). The total number of microglia was not increased significantly, but the activated
microglia was respectively increased by 79 and 109% in BDL and BDLHD rats (Figure 5B). In comparison with the control rats, the density of nNOS + neurons was relatively
unchanged in both BDL and BDLHD rats (Figure 5C). There was no noticeable change in the soma size (Figure 5D) and cell density (5E) of major output pyramidal neurons of sensorimotor cortex
in layer III and layer V.

Figure 4.Representative micrographs showing astrocytes and microglia in HE rats. The left column was GFAP-immunoreactive astrocytes (A-C) and right column was Iba1-immunoreactive microglia (D-F) in sham control (A and D), BDL (B and E) and BDLHD (C and F). At a high magnification, thickened processes (*) and bouton-like terminals (arrow)
were easily identified in BDL and BDLHD rats. The polyclonal Iba1 antibodies labeled
both inactive microglia (insert of D) and activated microglia (inserts of E and F). Bar = 300 μm in A-C, 20 μm for inserts.

Figure 5.The cytoarchitecture of sensorimotor cortex in HE rats. The soma size of astrocytes and layer III / V pyramidal neurons (A and B) and density of nNOS+ neurons (C) and microglia (D) were measured in sensorimotor cortex. *, p < 0.05 between the mark and control rats.

Alteration of dendritic structures on sensorimotor cortical pyramidal neurons in HE
rats

To investigate the morphological correlates of the effect ammonia on sensorimotor
integration in the brain, we studied the major output neurons, namely layer V pyramidal
neurons, of the sensorimotor cortex. Hyperammonemia did not appear to affect the apparent
shape of the dendritic arbor (Figure 6A-C), dendrogram (details not shown), dendritic length or number of terminal ends
(Figure 7A and B). We then scrutinized the dendritic spines on these neurons (Figure 8A). The spine density on proximal and distal segments of the apical and basal dendrites
of layer V pyramidal neurons was significantly reduced by 23-40% and 23-46% in BDL
and BDLHD rats, respectively, (Figure 8C).

Figure 6.Representative 3-dimensionally reconstructed pyramidal neurons. The layer V (A – C) pyramidal neurons of the primary sensorimotor cortex and hippocampal CA1 (D – F) pyramidal neurons were reconstructed with Neurolucida®. The apical dendritic trunk
was in red while the filled blue circle represents cell body. Branches of each basal
dendritic trunk were displayed with the same color. Roman numerals and horizontal
bars on the left of each drawing mark the cortical layers. Bar = 200 μm in A-C and 100 μm in D-F.

Figure 7.The dendritic arbor of pyramidal neurons was analyzed in HE rats. The dendritic arbors of layer V (A and B) pyramidal neurons of the primary sensorimotor cortex and hippocampal CA1 (C and D) pyramidal neurons were analyzed.

Figure 8.The spine loss of pyramidal neurons in HE rats. The spine density on layer V (A) pyramidal neurons of the primary sensorimotor cortex and hippocampal CA1 (B) pyramidal neurons was analyzed. Representative micrographs of basal segment and distal
apical segment of dendrite were illustrated in A and B. Spine density was measured and analyzed in C and D. *, p < 0.05 between the mark and control rats. Bar = 10 μm for all photograph.

For the spatial learning memory functions, we focused on the hippocampal CA1 pyramidal
neurons to explore possible morphological changes induced by hyperammonemia. As in
the layer V pyramidal neurons of sensorimotor cortex, hyperammonemia also had no effect
on the dendritic arbor of hippocampal CA1 pyramidal neurons (Figure 6D-F, 7C and 7D). The spine density on the basal dendrite and proximal and distal segments of the
apical dendrites of CA1 pyramidal neurons was significantly reduced by 27-47% and
24-40% in BDL and BDLHD rats, respectively, (Figure 8B and D).

Discussion

This study has succeeded in establishing a HE model in rats through ligation of the
common bile duct followed by feeding the rats with diet containing ammonium acetate
which results in hyperammonemia. More importantly, we have shown that the induced
hyperammonemia compromised the sensorimotor integration and spatial learning memory.
Moreover, at the cellular level, the astrocytes increased in cell size by 55-65%.
The total microglial number was not significantly increased but the frequency of activated
microglia was increased by 79-109%. Very interestingly, the dendritic arbors of layer
V and CA1 pyramidal neurons in the primary sensorimotor cortex and hippocampus were
not affected. A striking change, however, occurred at the dendritic spines whose density
was significantly decreased in HE rats. These changes were consistently observed on
all segments of the basal and apical dendrites. On the other hand, changes in dendritic
structures were revealed in sparse-fur mice, which are deficient in ornithine transcarbamylase.
In this congenital metabolic deficiency, the layer V pyramidal neurons in frontoparietal
cortex displayed retraction of basal dendritic arbor and decrease in spine density
of dendritic terminal [23]. The reduced complexity in basal dendritic arbor in spf/Y mice may have the following explanations. Firstly, ornithine transcarbamylase deficiency
might affect the dendritic maturation of cortical pyramidal neurons. In general, dendrite
arbors on central neurons reach their normal mature size during 3rd~4th postnatal weeks, and the synaptic transmission is pivotal to the proper development
of mature central neuronal architecture [24,25]. It is speculated that in spf/Y mice, the dendritic arbors of cortical pyramidal neurons might not reach their
full maturation. Secondly, in our HE model, the duration of ammonia influence is less
than one month. This may be another possible explanation for the discrepancy in results
between that of the above authors and ours. In addition, the above authors had used
Golgi-Kopsch method to reveal the basilar dendritic tree of layer V pyramidal cells
in frontoparietal cortex. The Golgi labels neurons capriciously and often results
in overlapping and incomplete dendritic arbors in sections to impede analysis [26]. In the present study, we employed intracellular dye injection [20-22,27,28] to reveal the dendritic arbors of the studied pyramidal neurons. This allowed us
to study specifically identified layer V and CA1 pyramidal neurons. Neurons, well-spaced
apart, could be individually filled with no time constraint. With proper orientation,
we were able to preserve most of the dendritic arbors for instance of the relatively
large layer V and CA1 pyramidal neurons close to completeness in a 350 μm-thick brain
slice.

Unlike dendritic arbors, dendritic spines are highly motile structures that have been
shown to be swiftly and dynamically modulated by many factors such as changes in environment
[29], gonadal hormones [27,28,30], physical compression and decompression [21,22], fatigue [20], insults such as axonal injury [31], deafferentation [32], and aging [33]. Here, we have shown that hyperammonemia significantly decreased the spine density
in layer V sensorimotor cortical neurons (23-46%) and in hippocampal CA1 pyramidal
neurons (24-47%). The dendritic spines of layer V pyramidal neurons in frontoparietal
cortex displayed more than 60% loss in sparse-fur mice [23]. In the clinic, threshold to evoke peripheral motor responses to transcranial magnetic
stimulation of the primary cortical motor area was increased in the presence of hepatic
encephalopathy, and this might be attributed to an ammonia induced loss of glutamatergic
excitatory synaptic inputs to cortical pyramidal neurons [34,35]. Because there was no significant change in cell density, soma size of layer V pyramidal
neurons as well as there was no evidence of neuronal death in the sensorimotor cortex,
it is suggested that the significant reduction in spine density of cortical pyramidal
neurons had contributed to the behavioral dysfunction as observed in the present HE
rats.

As far as can be ascertained, there is no defined mechanism to explain the spine loss
of cortical pyramidal neurons in HE model rats. It is speculated that this may be
multifactorial. Thus, the possibility of involvement of neuroglia activation or oxidative
stress is considered. Microglia was robustly activated and underwent proliferation
in hyperammonemia [36,37]. The microglia proliferation and astrocytes swelling might further increase the surrounding
pressure which could decrease the dendritic spines of cortical pyramidal neurons [21]. Recent studies have shown that interaction of microglia with synapses contributes
to synaptic remodeling during development [38] and adult [39]. The oxidative stress might be another factor causing decrease in the dendritic spines
of cortical pyramidal neurons. There is evidence that hyperammonemia could enhance
the production of ROS/RNOS in astrocytes [36,40]. Excessive ammonia in synaptic cleft may be mediated by an excitotoxic mechanism,
oxidative stress and nitric oxide (NO) production in cortical neurons [41]. These oxidative stresses further inhibit the synaptic transmission and promote the
synaptic remodeling. Our ongoing studies also found that high oxidative stress, induced
by D-galactose, significantly decreases the spine density of layer V sensorimotor
cortical neurons and hippocampal CA1 pyramidal neurons, and, remarkably, exogenous
antioxidant can fully restore it (unpublished data).

In HE rats, the astrocytes showed enhanced GFAP immunoreactivity, increase in soma
size and swollen end-feet. Similar results of astrocyte swelling were observed in
vivo [37] and in vitro [42,43] in rats. Astrocytic reaction is a hallmark feature of brain edema and its complications
(intracranial hypertension, brain herniation) in HE patients [44]. Astrocyte swelling may be caused by over-expression of aquaporin-4 protein [42,45], or an auto-amplificatory loop between ROS/RNOS formation and astrocyte swelling
[36,40]. Hyperammonemia is also frequently complicated by systemic inflammation including
increasing systemic and cerebral levels of vascular endothelial growth factor (VEGF),
Tumor Necrosis Factor (TNF)-alpha and the interleukins (IL)-1beta and IL-6 [46]. The VEGF may stimulate liver regeneration but it can also be pro-inflammatory, activating
endothelial cells and increasing permeability, actions mediated through Src kinase
signaling [47]. These proinflammatory cytokines progress in parallel with the severity of astrocyte
swelling [46]. The alterations in blood-brain barrier remain unclear although some studies have
shown disruption of tight junction proteins indicative of involvement of blood-brain
barrier in cellular swelling [48,49]. Hypertrophy of end-feet of astrocytes was evident after BDL surgery, but there was
no noticeable difference between the BDL and BDLHD rats. More studies are desirable
to confirm whether the enlarged end-feet may be correlated with the blood-brain barrier
damage in BDL rat model. A feature worthy of note is that hyperammonemia promotes
the astrocyte swelling but has no affect on soma area of layer III and Layer V pyramidal
neurons in sensorimotor cortex. In vitro culture study showed that NH4Cl could promote the swelling of culture astrocytes and microglia in a glutamine-synthesis
dependent way but has no effect on cell volume of cultured neurons [36].

Conclusion

Hyperammonemia, in addition to affecting peripheral organs, also alters the structure
of astrocytes and central neurons. It enhances the astrocyte swelling and microglia
activation; moreover, it significantly decreases the spine density of layer V sensorimotor
cortical neurons and hippocampal CA1 pyramidal neurons, which may be the underlying
cause for the motor and intellectual impairments associated with HE patients.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

BNW, GFT, YJW and YSH contributed to the acquisition of data, analysis, interpretation
and reconstruction of the neurons. JRC and TJW designed the study, participated in
analysis and interpretation of data, and finalized the text. All authors read and
approved the final manuscript.

Acknowledgements

This work was supported by research grants from the National Science Council of Taiwan
to Chen, J-R (NSC102-2320-B-005-001-MY3), Wang, T-J (NSC-95-2320-B-438-001), Wang,
Y-J (NSC100-2320-B-320-002) and Tseng, G-F (NSC101-2320- B-320-001) and grants from
the Tzu-Chi University to Wang, Y-J and Tseng, G-F (TCIRP98006).